Automatic retrieval of single microchimeric cells and verification of identity by on-chip multiplex PCR

Maternal cells have recently been found in the circulation and tissues of mothers' immune-competent children, including in adult life, and is referred to as maternal microchimerism (MMc). Whether MMc confers benefits during development or later in life or sometimes has adverse effects is unknown. Type 1 diabetes (T1D) is an autoimmune disease that primarily affects children and young adults. To identify and quantify MMc, we developed a panel of quantitative PCR assays targeting nontransmitted, nonshared maternal-specific HLA alleles. MMc was assayed in peripheral blood from 172 individuals, 94 with T1D, 54 unaffected siblings, and 24 unrelated healthy subjects. MMc levels, expressed as the genome equivalent per 100,000 proband cells, were significantly higher in T1D patients than unaffected siblings and healthy subjects. Medians and ranges, respectively, were 0.09 (0-530), 0 (0-153), and 0 (0-7.9). Differences between groups were evident irrespective of HLA genotypes. However, for patients with the T1D-associated DQB1*0302-DRB1*04 haplotype, MMc was found more often when the haplotype was paternally (70%) rather than maternally transmitted (14%). In other studies, we looked for female islet beta cells in four male pancreases from autopsies, one from a T1D patient, employing FISH for X and Y chromosomes with concomitant CD45 and beta cell insulin staining. Female islet beta cells (presumed maternal) formed 0.39-0.96% of the total, whereas female hematopoietic cells were very rare. Thus, T1D patients have higher levels of MMc in their circulation than unaffected siblings and healthy individuals, and MMc contributes to islet beta cells in a mother's progeny.

During pregnancy, fetal CD34+ cells enter the maternal circulation, persist for decades, and create a state of physiologic microchimerism. Many studies have confirmed the residual presence of fetal cells in maternal blood and tissues following pregnancy. Fetal cells may respond to maternal injury by developing multilineage capacity in maternal organs. To verify that fetal microchimeric cells express markers of epithelial, leukocyte, and hepatocyte differentiation within maternal organs. Archived paraffin-embedded tissue section specimens from 10 women who had male offspring and were previously found to have high numbers of microchimeric cells, and 11 control women who had no prior male pregnancies. Male cells were identified by fluorescence in situ hybridization, using X and Y chromosome-specific probes, followed by histologic and immunochemical studies using anticytokeratin (AE1/AE3) as a marker of epithelial cells, anti-CD45 as a leukocyte marker, and heppar-1 as a hepatocyte marker. Percentage of microchimeric cells expressing nonhematopoietic markers. A total of 701 male (XY+) microchimeric cells were identified (mean [SD], 227 [128] XY+ cells per million maternal cells). In maternal epithelial tissues (thyroid, cervix, intestine, and gallbladder), 14% to 60% of XY+ cells expressed cytokeratin. Conversely, in hematopoietic tissues, such as lymph nodes and spleen, 90% of XY+ cells expressed CD45. In 1 liver sample, 4% of XY+ cells expressed heppar-1. Histologic and immunochemical evidence of differentiation, as assessed by independent observers, was highly concordant (kappa = 0.72). The detection of microchimeric male cells, bearing epithelial, leukocyte, or hepatocyte markers, in a variety of maternal tissue specimens suggests the presence of fetal cells that may have multilineage capacity.

Some so-called autoimmune diseases in women might be alloimmune and represent a chronic graft-versus-host response attributable to transplacentally acquired fetal cells. Thyroid disease is more common in women than men, and post partum exacerbation of thyroiditis is common. Our aim was to investigate whether there is an association between fetal cell microchimerism and thyroid disease in women. Surgical specimens were obtained from 29 women who underwent thyroidectomy for various thyroid disorders. Control specimens were taken from clinically and histologically normal thyroids obtained at necropsy from eight women who died from unrelated conditions. Medical records and pregnancy histories were reviewed. Fluorescence in-situ hybridisation analysis was done with probes specific for X and Y chromosomes. Slides were examined with a fluorescence microscope to detect the presence of male cells-with one X and one Y signal in the nucleus-among maternal cells containing two X signals. Male cells were seen in thyroid sections from 16 patients but not in those from controls (p=0.01). Male cells (1-165 per slide) were seen individually or in clusters in all thyroid diseases and were not restricted to inflammatory thyroid diseases. In one patient with a progressively enlarging goitre, we noted fully differentiated male thyroid follicles closely attached to and indistinguishable from the rest of the thyroid. Our findings suggest a relation between fetal cell microchimerism and thyroid disease. Furthermore, fetal stem cells might be capable of differentiation into mature thyroid follicles in their mothers with favourable environmental and developmental factors.